Inverse Trigonometric Functions Miscellaneous Solutions


Short Intro

In this post, students can find complete step-by-step solutions for the Miscellaneous Exercise of Class 12 Maths Chapter 2 – Inverse Trigonometric Functions. This exercise includes principal values, identities, equations, simplification of inverse trigonometric expressions, and important MCQs based on the latest NCERT syllabus.


Quick Information Box

Item Details
Board NCERT / CBSE
Class 12
Subject Mathematics
Chapter Inverse Trigonometric Functions
Exercise Miscellaneous Exercise
Main Topics Principal Values & Properties

Concepts Used (Topics Covered)

  • Principal Value Branch
  • Inverse Sine Function
  • Inverse Cosine Function
  • Inverse Tangent Function
  • Trigonometric Identities
  • Simplification of Expressions
  • Solving Trigonometric Equations
  • Properties of Inverse Trigonometric Functions

The chapter explains domains, ranges and principal value branches of inverse trigonometric functions.


Important Formulas

Principal Value Ranges

sin1x[π2,π2]\sin^{-1}x\in\left[-\frac{\pi}{2},\frac{\pi}{2}\right]sin−1x∈[−2π​,2π​]

cos1x[0,π]\cos^{-1}x\in[0,\pi]cos−1x∈[0,π]

tan1x(π2,π2)\tan^{-1}x\in\left(-\frac{\pi}{2},\frac{\pi}{2}\right)tan−1x∈(−2π​,2π​)


Questions & Step-by-step Solutions

Question 1

Find:

cos1(cos13π6)\cos^{-1}(\cos\frac{13\pi}{6})

Solution

We know:

cos(13π/6) = cos(π/6)

Hence:

cos⁻¹(cos 13π/6) = cos⁻¹(cos π/6)

Principal value of cosine inverse lies in:

[0, π]

Therefore:

Answer = π/6

Question 2

Find:

tan1(tan7π6)\tan^{-1}(\tan\frac{7\pi}{6})

Solution

We know:

tan(7π/6)=tan(π/6)

Principal value range of:

tan⁻¹x

is:

(-π/2, π/2)

Therefore:

Answer = π/6

Question 3

Prove that:

2sin135=tan12472\sin^{-1}\frac{3}{5}=\tan^{-1}\frac{24}{7}

Solution

Let:

θ = sin⁻¹(3/5)

Then:

sin θ = 3/5

Using right triangle:

cos θ = 4/5

Hence:

tan θ = 3/4

Using double angle formula:

tan 2θ = 2tanθ/(1−tan²θ)

Substituting:

tan2θ = 24/7

Therefore:

2θ = tan⁻¹(24/7)

Hence proved.


Question 4

Prove:

sin1817+sin135=tan17736\sin^{-1}\frac{8}{17}+\sin^{-1}\frac{3}{5}=\tan^{-1}\frac{77}{36}

Solution

Let:

A = sin⁻¹(8/17)

and

B = sin⁻¹(3/5)

Then:

tanA = 8/15

and:

tanB = 3/4

Using:

tan(A+B)

formula:

tan(A+B)=77/36

Therefore:

A+B = tan⁻¹(77/36)

Hence proved.


Question 5

Prove:

cos145+cos11213=cos13365\cos^{-1}\frac{4}{5}+\cos^{-1}\frac{12}{13}=\cos^{-1}\frac{33}{65}

Solution

Using compound angle formulas and principal values:

Result = cos⁻¹(33/65)

Hence proved.


Question 6

Prove:

cos11213+sin135=sin15665\cos^{-1}\frac{12}{13}+\sin^{-1}\frac{3}{5}=\sin^{-1}\frac{56}{65}

Solution

Convert inverse cosine into trigonometric ratios.

Using addition formulas:

Result = sin⁻¹(56/65)

Hence proved.


Question 7

Prove:

tan16316=sin1513+cos135\tan^{-1}\frac{63}{16}=\sin^{-1}\frac{5}{13}+\cos^{-1}\frac{3}{5}

Solution

Using:

tan(A+B)

formula and triangle identities:

LHS = RHS

Hence proved.


Question 8

Prove:

tan11x1+x=12cos1x\tan^{-1}\sqrt{\frac{1-x}{1+x}}=\frac{1}{2}\cos^{-1}x

Solution

Put:

x = cos2θ

Then:

(1−x)/(1+x)=tan²θ

Hence:

tan⁻¹√((1−x)/(1+x)) = θ

Also:

θ = ½ cos⁻¹x

Hence proved.


Question 9

Prove the identity.

Solution

Using half-angle formulas and simplification:

LHS = RHS

Hence proved.


Question 10

Prove the identity.

Solution

Put:

x = cos2θ

Use standard trigonometric identities.

After simplification:

LHS = RHS

Hence proved.


Question 11

Solve:

2tan1(cosx)=tan1(2cosecx)2\tan^{-1}(\cos x)=\tan^{-1}(2\cosec x)

Solution

Using:

tan2A = 2tanA/(1−tan²A)

we get:

x = π/2

Question 12

Solve:

tan11x1+x=12tan1x\tan^{-1}\frac{1-x}{1+x}=\frac{1}{2}\tan^{-1}x

Solution

Using tangent half-angle identities:

x = 1

Question 13

Find:

sin(tan1x)\sin(\tan^{-1}x)

Solution

Let:

θ = tan⁻¹x

Then:

tanθ = x

Using right triangle:

sinθ = x/√(1+x²)

Therefore:

Answer = x/√(1+x²)

Correct option:

(D)

Question 14

If:

sin1(1x)2sin1x=π2\sin^{-1}(1-x)-2\sin^{-1}x=\frac{\pi}{2}

Solution

After simplification:

x = 1/2

Correct option:

(D)

Common Mistakes

  • Ignoring principal value ranges
  • Confusing sin⁻¹x with 1/sinx
  • Using wrong quadrant values
  • Mistakes in addition formulas
  • Forgetting domain restrictions

Exam Tips

  • Always remember principal branches.
  • Draw triangles for inverse trigonometric problems.
  • Learn standard identities thoroughly.
  • Practice simplification regularly.

Practice MCQs

MCQ 1

Principal value range of:

sin1x\sin^{-1}x

is:

A. [0,π]
B. [−π/2, π/2]
C. (−π,π)
D. R

Answer:

B. [−π/2, π/2]

MCQ 2

Value of:

tan1(1)\tan^{-1}(1)

is:

A. 0
B. π/2
C. π/4
D. π

Answer:

C. π/4

MCQ 3

Inverse cosine function range is:

A. [0,π]
B. [−π/2,π/2]
C. R
D. (0,2π)

Answer:

A. [0,π]

FAQ Section

What is principal value?

The value lying in the principal branch of inverse trigonometric function.


What is range of sin⁻¹x?

[π2,π2]\left[-\frac{\pi}{2},\frac{\pi}{2}\right]


Is sin⁻¹x equal to 1/sinx?

No.

sin⁻¹x means inverse sine function.

What is range of tan⁻¹x?

(π2,π2)\left(-\frac{\pi}{2},\frac{\pi}{2}\right)


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